A flower-shaped structure only a few micrometers in size made of a nickel-iron alloy can concentrate and locally enhance ...

Nearly two centuries after Faraday's failed attempts, scientists have demonstrated that Earth's continuous spin can directly ...

Tiny magnetic "flowers" engineered by physicist Anna Palau are redefining how we manipulate magnetic fields. These ...

Imagine navigating a virtual reality with contact lenses or operating your smartphone underwater: This and more could soon be ...

Scientists know well how conventional materials conduct heat. However, things are not as straightforward under extreme ...

A flower-shaped structure only a few micrometres in size made of a nickel-iron alloy can concentrate and locally enhance magnetic fields. The size of the effect can be controlled by varying the ...

The ability to conduct heat is one of the most fundamental properties of matter, crucial for engineering applications. Scientists know well how conventional materials, such as metals and insulators, ...

It looked still to you before because you were moving with it. We have this same problem with electric and magnetic fields. Depending on your reference frame, what appears to be a magnetic force ...

Frequency Electronics said it has been awarded a subcontract from Leidos to develop a nitrogen vacancy diamond magnetometer to detect magnetic fields. The provider of precision timing and frequency ...

Scientists have developed a tiny flower-shaped structure that’s made of a nickel-iron alloy to concentrate and locally ...

Room-temperature magnetic and electronic traits make phosphorene nanoribbons promising for next-gen, energy-efficient nanoelectronics.

A University of Toronto Engineering team has collaborated with researchers in the Wilfred and Joyce Posluns Centre for Image ...